It has previously been shown in vivo that bovine papillomavirus represses its late gene expression via a 5' splice site sequence located upstream of the late polyadenylation signal. Here, the mechanism of repression is determined by in vitro analysis. U1 snRNP binding to the 5' splice site results in inhibition of polyadenylation via a direct interaction with poly(A) polymerase (PAP). Although the inhibitory mechanism is similar to that used in U1A autoregulation, U1A within the U1 snRNP does not contribute to PAP inhibition. Instead the U1 70K protein, when bound to U1 snRNA, both interacts with and inhibits PAP. Conservation of the U1 70K inhibitory domains suggests that polyadenylation regulation via PAP inhibition may be more widespread than previously thought.
Alternative cleavage and polyadenylation (APA) results in mRNA isoforms containing different 3’ untranslated regions (3’UTRs) and/or coding sequences. How core cleavage/polyadenylation (C/P) factors regulate APA is not well understood. Using siRNA knockdown coupled with deep sequencing, we found that several C/P factors can play significant roles in 3’UTR-APA. Whereas Pcf11 and Fip1 enhance usage of proximal poly(A) sites (pAs), CFI-25/68, PABPN1 and PABPC1 promote usage of distal pAs. Strong cis element biases were found for pAs regulated by CFI-25/68 or Fip1, and the distance between pAs plays an important role in APA regulation. In addition, intronic pAs are substantially regulated by splicing factors, with U1 mostly inhibiting C/P events in introns near the 5’ end of gene and U2 suppressing those in introns with features for efficient splicing. Furthermore, PABPN1 inhibits expression of transcripts with pAs near the transcription start site (TSS), a property possibly related to its role in RNA degradation. Finally, we found that groups of APA events regulated by C/P factors are also modulated in cell differentiation and development with distinct trends. Together, our results support an APA code where an APA event in a given cellular context is regulated by a number of parameters, including relative location to the TSS, splicing context, distance between competing pAs, surrounding cis elements and concentrations of core C/P factors.
Dendrite branching has an important role in normal brain function. Here we report that overexpression of cypin, a protein that has guanine deaminase activity and is expressed in developing processes in rat hippocampal neurons, results in increased dendrite branching in primary culture. Mutant cypin proteins that lack guanine deaminase activity act in a dominant-negative manner when expressed in primary neurons. Furthermore, we knocked down cypin protein levels using a new strategy: expressing a 5' end-mutated U1 small nuclear RNA (snRNA) to inhibit maturation of cypin mRNA. Neurons that express this mutant snRNA show little or no detectable cypin protein and fewer dendrites than normal. In addition, we found that cypin binds directly to tubulin heterodimers and promotes microtubule polymerization. Thus, our results demonstrate a new pathway by which dendrite patterning is regulated, and we also introduce a new method for decreasing endogenous protein expression in neurons.
Interactions required for inhibition of poly(A) polymerase (PAP) by the Ul snRNP-specific UlA protein, a reaction whose function is to autoregulate UlA protein production, are examined. PAP inhibition requires a substrate RNA to which at least two molecules of UlA protein can bind tightly, but we demonstrate that the secondary structure of the RNA is not highly constrained. A mutational analysis reveals that the carboxy-terminal 20 amino acids of PAP are essential for its inhibition by the UlA-RNA complex. Remarkably, transfer of these amino acids to yeast PAP, which is otherwise not affected by UlA protein, is sufficient to confer UlA-mediated inhibition onto the yeast enzyme. A glutathione S-transferase fusion protein containing only these 20 PAP residues can interact in vitro with an RNA-UIA protein complex containing two UlA molecules, but not with one containing a single UlA protein, explaining the requirement for two UlA-binding sites on the autoregulatory RNA element. A mutational analysis of the UlA protein demonstrates that amino acids 103-119 are required for PAP inhibition. A monomeric synthetic peptide consisting of the conserved UlA amino acids from this region has no detectable effect on PAP activity. However, the same UlA peptide, when conjugated to BSA, inhibits vertebrate PAP. In addition to this activity, the UlA peptide-BSA conjugate specifically uncouples splicing and 3'-end formation in vitro without affecting uncoupled splicing or 3'-end cleavage efficiencies. This suggests that the carboxy-terminal region of PAP with which it interacts is involved not only in UlA autoregulation but also in the coupling of splicing and 3'-end formation.[Key Words: RNA processing; pre-mRNA splicing; cleavage and polyadenylation; UlA protein; poly(A) polymerase]
The cDNA for PRMT7, a recently discovered human protein-arginine methyltransferase (PRMT), was cloned and expressed in Escherichia coli and mammalian cells. Immunopurified PRMT7 actively methylated histones, myelin basic protein, a fragment of human fibrillarin (GAR) and spliceosomal protein SmB. Amino acid analysis showed that the modifications produced were predominantly monomethylarginine and symmetric dimethylarginine (SDMA). Examination of PRMT7 expressed in E. coli demonstrated that peptides corresponding to sequences contained in histone H4, myelin basic protein, and SmD3 were methylated. Furthermore, analysis of the methylated proteins showed that symmetric dimethylarginine and relatively small amounts of monomethylarginine and asymmetric dimethylarginine were produced. SDMA was also formed when a GRG tripeptide was methylated by PRMT7, indicating that a GRG motif is by itself sufficient for symmetric dimethylation to occur. Symmetric dimethylation is reduced dramatically compared with monomethylation as the concentration of the substrate is increased. The data demonstrate that PRMT7 (like PRMT5) is a Type II methyltransferase capable of producing SDMA modifications in proteins.
The human U1A protein‐U1A pre‐mRNA complex and the relationship between its structure and function in inhibition of polyadenylation in vitro were investigated. Two molecules of U1A protein were shown to bind to a conserved region in the 3′ untranslated region of U1A pre‐mRNA. The secondary structure of this region was determined by a combination of theoretical prediction, phylogenetic sequence alignment, enzymatic structure probing and molecular genetics. The U1A binding sites form (part of) a complex secondary structure which is significantly different from the binding site of U1A protein on U1 snRNA. Studies with mutant pre‐mRNAs showed that the integrity of much of this structure is required for both high affinity binding to U1A protein and specific inhibition of polyadenylation in vitro. In particular, binding of a single molecule of U1A protein to U1A pre‐mRNA is not sufficient to produce efficient inhibition of polyadenylation.
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